Binding of protected video content to video player with block cipher hash

ABSTRACT

A video player sends a video content identifier and a video player identifier through a network to a server. The video content identifier identifies video content. The video player identifier identifies the video player. Further, a first subset of encrypted video content and an initialization vector are received from a server. In addition, a hash of the video player identifier is generated. The first subset of the encrypted video content is decrypted with a decryption key to generate a first result. Further, a first operation on the initialization vector and the hash is performed to generate a second result. In addition, a second operation is performed on the first result and the second result to generate a first subset of plaintext of video content.

TECHNICAL FIELD

This disclosure generally relates to encryption. More particularly, the disclosure relates to encrypted video content.

BACKGROUND

Some current video playback configurations for playback of video content downloaded from the Internet utilize an encryption mechanism to protect the video content. As an example, when a user would like to play video content on a website, the user may be required to have a video player that includes a scripting code, which may be utilized to initiate and load playback of the video content. The scripting code may be included within a file as part of the video player. The video content may be loaded as an asset into the video player at runtime when downloaded.

Further, the video player may be integrated with advertisements, customer graphics, and other content provider specific information that may be utilized to generate revenue from playback of the video content. Accordingly, content providers and advertisers have to ensure that the video player that is provided to a user is the video player that is utilized to play the provided content so that the advertisements and other revenue generating mechanisms are present in the player utilized by the user to play the content. However, current approaches are vulnerable to users retrieving the scripting code from the provided video player and putting the scripting code into their own video players so that they can avoid the advertisements.

A current approach involves the video player performing a hash on the scripting code and sending the hashed scripting code to a server for verification. However, that approach involves the possibility of the hashed scripting code being intercepted en route from the video player to the server. In other words, a security vulnerability may arise if the hashed scripting code is moved from the video player to the server.

SUMMARY

In one aspect of the disclosure, a computer program product is provided. The computer program product includes a computer useable medium having a computer readable program. The computer readable program when executed on a computer causes the computer to receive, at a server, a media content identifier and a media player identifier from a media player through a network. The media content identifier identifies media content. The media player identifier identifies a media player. Further, the computer readable program when executed on the computer causes the computer to provide the media player identifier to a function generator to generate an indicium of the media player identifier. In addition, the computer readable program when executed on the computer causes the computer to perform a first operation on an initialization vector and the indicium to generate a first result. The computer readable program when executed on the computer also causes the computer to perform a second operation on a first subset of plaintext and the first result to generate a second result. The plaintext is the media content. Further, the computer readable program when executed on the computer causes the computer to encrypt the second result with an encryption key to generate a first set of ciphertext.

In another aspect of the disclosure, a process is provided. The process sends, from a video player, a video content identifier and a video player identifier through a network to a server. The video content identifier identifies video content. The video player identifier identifies the video player. Further, the process receives, from the server, a first subset of encrypted video content and an initialization vector. In addition, the process generates a hash of the video player identifier. The process also decrypts the first subset of the encrypted video content with a decryption key to generate a first result. Further, the process performs a first operation on the initialization vector and the hash to generate a second result. In addition, the process performs a second operation on the first result and the second result to generate a first subset of plaintext of video content.

In yet another aspect of the disclosure, system is provided. The system includes a communication module that receives, at a server, a video content identifier and a video player identifier from a video player through a network. The video content identifier identifies video content. The video player identifier identifies a video player. Further, the system includes a hash generator that generates a hash of the video player identifier that is utilized as an initialization vector. In addition, the system includes a processor that (i) performs a first operation on a first subset of plaintext and the initialization vector to generate a first result and (ii) encrypts the first result with an encryption key to generate a first set of ciphertext, the plaintext being the video content.

In another aspect of the disclosure, a computer program product is provided. The computer program product includes a computer useable medium having a computer readable program. The computer readable program when executed on a computer causes the computer to receive, at a server, a video content identifier and a video player identifier from a video player through a network. The video content identifier identifies video content. The video player identifier identifies a video player. Further, the computer readable program when executed on the computer causes the computer to provide the video player identifier to a hash generator to generate a hash of the video player identifier such that the hash is an encryption key. In addition, the computer readable program when executed on the computer causes the computer to encrypt plaintext of the video content with the encryption key to generate ciphertext.

In yet another aspect of the disclosure, a process is provided. The process receives, at a server, a video content identifier and a video player identifier from a video player through a network. The video content identifier identifies video content. The video player identifier identifies a video player. Further, the process provides the video player identifier to a hash generator to generate a hash of the video player. In addition, the process encrypts plaintext of the video content with the encryption key to generate ciphertext. The process also encrypts the encryption key with the hash to generate an encrypted encryption key.

In another aspect of the disclosure, a system is provided. The system includes a communication module that receives, at a server, a video content identifier and a video player identifier from a video player through a network. The video content identifier identifies video content. The video player identifier identifies a video player. Further, the system includes a hash generator that generates a hash of the video player identifier such that the hash is an encryption key. In addition, the system includes a processor that encrypts plaintext of the video content with the encryption key to generate ciphertext.

BRIEF DESCRIPTION OF THE DRAWINGS

The above-mentioned features of the present disclosure will become more apparent with reference to the following description taken in conjunction with the accompanying drawings wherein like reference numerals denote like elements and in which:

FIG. 1 illustrates an encryption binding configuration 100 that utilizes a block cipher initialization vector.

FIG. 2 illustrates a hashed cipher block chaining encryption configuration 200.

FIG. 3 illustrates a hashed cipher block chaining decryption configuration 300.

FIG. 4A illustrates a process 400 that may be utilized for encryption.

FIG. 4B illustrates a process 450 that may be utilized for decryption.

FIG. 5 illustrates a system configuration 500 that may be utilized to bind protected video content to a video player.

FIG. 6 illustrates an encryption binding configuration that utilizes the hash 110 of the video player identifier as the encryption key to encrypt the video content or as an encryption key to encrypt the encryption key that encrypts the video content.

FIG. 7 illustrates a process that utilizes the hash of the video player identifier as the encryption key to encrypt the video content.

FIG. 8 illustrates a process that that utilizes the hash of the video player identifier as an encryption key to encrypt the encryption key that encrypts the video content.

DETAILED DESCRIPTION

A configuration is provided that binds encrypted video to a video player. The ‘fingerprint’, e.g., an identifier, of the video player is integrated into the video itself. As a result, the file including a scripting code that initiates download and playback is prevented from being reused, modified, or hosted in alternate locations. Further, the scripting code that is playing back the video is ensured to be the scripting code that was created by the publisher. In addition, the scripting code is maintained securely as a hash of the scripting code is not sent from the video player to the server. The time of validating the video player is also reduced as a hash of the scripting code is not sent from the video player to the server.

In one embodiment, a cryptographic hash is calculated at the time of asset acquisition, i.e., video download, by both the server of the video content and the consumer of the video content, i.e., the video player. This cryptographic hash is then utilized as an encryption parameter for the encryption of the content.

FIG. 1 illustrates an encryption binding configuration 100 that utilizes a block cipher initialization vector. The encryption binding configuration includes a video player 102. As an example, a user may request that the video player 102 plays a video file 104. For instance, the video player 102 may be a SWF video player and the video file 104 may be a Flash SWF file. When making the request, the user sends a video player ID and a content ID of the video that the user would like to play with the video player 102. For example, the user may send the video player ID and the content ID to a video content provider 106 by utilizing an HTTP command, transmission signal, or the like. In one embodiment, the video content provider 106 is a website that plays video content. For example, a user may be able to search the website for a video of interest and play that video at the website. The video content provider may store the video content in a database. Further, the video content provider may store video player IDs in a database. The video content provider 106 may look up the video player ID and utilize a hash generator 108 to generate a hash 110 of the binary of the video player 102. In one embodiment, the hash 110 is pre-computed prior to the time of the request. In another embodiment, the hash 110 is generated at the time of the request. The video player may be utilized at a client. The client may be any type of computing device or reside on any type of computing device. As yet another example, an HTML5 video tag may be utilized. The content is delivered inside the HTML5 video tag, but the key setup, e.g., hashing of the video player or some other piece of data, occurs in a protected environment. Accordingly, the data traffic, e.g., the video, is delivered via the HTML5 video tag, but a secure configuration is utilized to protect the key derivation.

A cipher is an approach utilized for encryption and/or decryption. Further, a block cipher is a cipher that is utilized to encrypt and/or decrypt data of a fixed length, i.e., blocks. An initialization vector is an input provided to a block cipher that may be utilized for randomization. In one embodiment, the hash 110 is utilized as an initialization vector input into a block cipher. Further, the initialization vector, an encryption key, and video content 112 may then be provided to an encryption engine 114. The encryption engine may utilize the initialization vector and the encryption key as inputs to the block cipher to encrypt the video content 112 to generate an encrypted video 116. The encrypted video 116 may then be sent to the video player 102. In one embodiment, the video player 102 knows in advance the hash configuration that was utilized to generate the hash by the video content provider 106 and the block cipher that was utilized to encrypt the encrypted video 116. The video player 102 then calculates the hash 110 and utilizes the hash 110 to decrypt the encrypted video 116.

In one embodiment, a server 118 may comprise the content provider 106, the hash generator 108, and the encryption engine 114. Accordingly, the video player 102 may communicate with the server 118. In another embodiment, some or all of the content provider 106, the hash generator 108, and the encryption engine 114 may be implemented on different computing devices. The hash generator 108 is provided merely as an example of a function generator. The function generator may generate an indicium for the video player ID such as a hash.

The server 118 may incorporate the hash 110 of the video player ID into the protection of the video asset. Any hash configuration may be utilized. The hash 110 of the video player ID is not sent from the client to the server 118. As a result, the hash 110 may be kept or calculated in a secure location on the client and a secure location on the server without being exposed to the outside world. Both the server 118 and the client have the ability to calculate the hash 110 of the video player ID as both the server 118 and the client have access to the video file 104. The server 118 has access to the video file 104 as the server 118 may store copies of all video files and/or corresponding hashes. Further, the client has access to the video file 104 as the client utilizes the video file 104 to play back the video content 112.

By utilizing the hash 110 as a block cipher initialization vector to encrypt the video content 112, a pre-determined key may be utilized for the encryption. As a result, the same encryption key may be utilized any time the video content 112 is encrypted by the encryption engine 114. However, the encryption may be modified on different encryption actions as a result of the hash 110 being inputted into the block cipher.

FIG. 2 illustrates a hashed cipher block chaining encryption configuration 200. In one embodiment, an operation is performed on the hash 110 and an initialization vector 202. The operation may be an XOR or a variety of other operations. A subsequent operation is then performed on the result and a subset of plaintext 204. The result of the subsequent operation and an encryption key are then provided to a block cipher encryption engine 210 that encrypts the result into ciphertext 212.

An additional subset of plaintext 206 may also be encrypted by utilizing the hash 110. Instead of utilizing the initialization vector 202, an operation is performed on the hash 110 and the ciphertext 212. As an example, the operation may be an XOR. A further operation, e.g., an XOR, may then be performed on the result and the additional subset of plaintext 206. The result and the encryption key may then be provided to the block cipher encryption engine 210 for encryption of the result into additional ciphertext 214.

The hashed cipher block chaining may be utilized for the remaining of the blocks of plaintext. As an example, yet another subset of plaintext 208 may be provided to the block cipher encryption engine 210. Instead of utilizing the initialization vector 202, an operation is performed on the hash 110 and the ciphertext 214. As an example, the operation may be an XOR. A further operation, e.g., an XOR, may then be performed on the result and the other subset of plaintext 208. The result and the encryption key may then be provided to the block cipher encryption engine 210 for encryption of the result into additional ciphertext 216.

The illustrated hashed cipher block chaining encryption may be performed according to the following formula: C_(i)=E_(k)(P_(i) XOR (H XOR (C_(i)−1)), H XOR C₀=IV. The variable C is ciphertext, the function E is encryption, the variable P is plaintext, the variable H is hash, and the variable IV is initialization vector. In other words, an XOR is performed on the hash 110 and the initialization vector 202 for the first block of plaintext. An XOR operation is performed on the result and the first block of plaintext. That result is then encrypted. Subsequent blocks of data utilize the ciphertext from the previous block. An XOR operation is performed on the ciphertext from the previous block and the hash 110. Another XOR operation is then performed on that result and the plaintext. Encryption is then performed on that result.

Additional or fewer of blocks of plaintext may be encrypted. The examples provided herein are provided only for illustrative purposes.

A set of data 218 may then be sent to the video player 102. The set of data 218 may include the initialization vector 202 and the various blocks of ciphertext. The video player 202 may then decrypt the blocks of ciphertext by generating the hash 110 and then utilizing the hash, a decryption key, and the initialization vector 202 to decrypt the blocks of ciphertext.

In another embodiment, the hash 110 itself is utilized as the initialization vector 202. Accordingly, an operation would not have to be performed on the hash 110 and the initialization vector 202. Further, the initialization vector 202 would not have to be sent as part of the set of data 118 to the video player 102 as the video player 102 is capable of generating the hash 110.

In one embodiment, the encryption methodology that is utilized is symmetrical encryption. Accordingly, the same key may be utilized both for encryption and decryption. As a result, the client and the server may both store the same key. In another embodiment, the encryption methodology that is utilized is asymmetrical. Accordingly, different keys are utilized for encryption and decryption. Therefore, the server may store an encryption key whereas the client may store a decryption key.

FIG. 3 illustrates a hashed cipher block chaining decryption configuration 300. As an example, the video player 102 illustrated in FIG. 1 may utilize the hashed cipher block chaining decryption configuration 300 to decrypt the encrypted video content received from the video content provider 106. A block cipher decryption engine 302 utilizes a key to decrypt the block of ciphertext 212. Further, an operation is performed on the decrypted result. The operation may be an XOR operation or a variety of other operations. In addition, an operation, e.g., an XOR operation, is performed on the initialization vector and the hash 110. An operation, e.g., an XOR operation, is performed on that result and the decrypted result to generate the subset of plaintext 204.

The subsequent blocks utilize the ciphertext of the previous block rather than the initialization vector 202. The block cipher decryption engine 302 utilizes a key to decrypt the block of ciphertext 214. Further, an operation is performed on the decrypted result. The operation may be an XOR operation or a variety of other operations. In addition, an operation, e.g., an XOR operation, is performed on the previous block of ciphertext 212 and the hash 110. An operation, e.g., an XOR operation, is performed on that result and the decrypted result to generate the subset of plaintext 206.

In addition, the block cipher decryption engine 302 utilizes a key to decrypt the block of ciphertext 216. Further, an operation is performed on the decrypted result. The operation may be an XOR operation or a variety of other operations. In addition, an operation, e.g., an XOR operation, is performed on the previous block of ciphertext 214 and the hash 110. An operation, e.g., an XOR operation, is performed on that result and the decrypted result to generate the subset of plaintext 208.

In another embodiment, the hash 110 itself is utilized as the initialization vector 202. Accordingly, an operation would not have to be performed on the hash 110 and the initialization vector 202.

The illustrated hashed cipher block chaining decryption may be performed according to the following formula: P_(i)=D_(k)(C_(i) XOR (H XOR (C_(i)−1)), H XOR C₀=IV. The variable C is ciphertext, the function D is encryption, the variable P is plaintext, the variable H is hash, and the variable IV is initialization vector. In other words, a decryption of the first block of ciphertext is performed. An XOR is performed on that result and the result of an XOR performed on the initialization vector 202 and the hash 110 to generate the first set of plaintext. Subsequent blocks of data utilize the ciphertext from the previous block. An XOR operation is performed on the ciphertext from the previous block and the hash 110. Another XOR operation is then performed on that result and the decrypted subsequent block of ciphertext. Encryption is then performed on that result.

FIG. 4A illustrates a process 400 that may be utilized for encryption. At a process block 402, the process 400 receives, at a server, a video content identifier and a video player identifier from a video player through a network. The video content identifier identifies video content. The video player identifier identifies a video player. Further, at a process block 404, the process 400 provides the video player identifier to a hash generator to generate a hash of the video player identifier. In addition, at a process block 406, the process 400 performs a first operation on an initialization vector and the hash to generate a first result. At a process block 408, the process 400 also performs a second operation on a first subset of plaintext and the first result to generate a second result. The plaintext is the video content. Further, at a process block 410, the process 400 encrypts the second result with an encryption key to generate a first set of ciphertext.

FIG. 4B illustrates a process 450 that may be utilized for decryption. At a process block 452, the process 450 sends, from a video player, a video content identifier and a video player identifier through a network to a server. The video content identifier identifies video content. The video player identifier identifies the video player. Further, at a process block 454, the process 450 receives, from the server, a first subset of encrypted video content and an initialization vector. In addition, at a process block 456, the process 450 generates a hash of the video player identifier. At a process block 458, the process 450 also decrypts the first subset of the encrypted video content with a decryption key to generate a first result. Further, at a process block 460, the process 450 performs a first operation on the initialization vector and the hash to generate a second result. In addition, at a process block 462, the process 450 performs a second operation on the first result and the second result to generate a first subset of plaintext of video content.

Any of the configurations described herein may be utilized with a variety of computing devices. A computing device may be personal computer (“PC”), laptop, notebook, smartphone, cell phone, tablet device, personal digital assistant (“PDA”), kiosk, or the like.

FIG. 5 illustrates a system configuration 500 that may be utilized to bind protected video content to a video player. In one embodiment, a video player binding module 502 interacts with a memory 504 and a processor 506. In one embodiment, the system configuration 500 is suitable for storing and/or executing program code and is implemented using a general purpose computer or any other hardware equivalents. The processor 506 is coupled, either directly or indirectly, to the memory 504 through a system bus. The memory 504 can include local memory employed during actual execution of the program code, bulk storage, and/or cache memories which provide temporary storage of at least some program code in order to reduce the number of times code must be retrieved from bulk storage during execution.

The Input/Output (“I/O”) devices 508 can be coupled directly to the system configuration 500 or through intervening input/output controllers. Further, the I/O devices 508 may include a keyboard, a keypad, a mouse, a microphone for capturing speech commands, a pointing device, and other user input devices that will be recognized by one of ordinary skill in the art. Further, the I/O devices 508 may include output devices such as a printer, display screen, or the like. Further, the I/O devices 508 may include a receiver, transmitter, speaker, display, image capture sensor, biometric sensor, etc. In addition, the I/O devices 508 may include storage devices such as a tape drive, floppy drive, hard disk drive, compact disk (“CD”) drive, etc. Any of the modules described herein may be single monolithic modules or modules with functionality distributed in a cloud computing infrastructure utilizing parallel and/or pipeline processing.

Network adapters may also be coupled to the system configuration 500 to enable the system configuration 500 to become coupled to other systems, remote printers, or storage devices through intervening private or public networks. Modems, cable modems, and Ethernet cards are just a few of the currently available types of network adapters.

In yet another embodiment, the video player 102 may be utilized to protect the video content without a hashed block cipher methodology as described with respect to FIGS. 2 and 3. The hash 110 of the video player identifier may be utilized as the encryption key to encrypt the video content or as an encryption key to encrypt the encryption key that encrypts the video content.

FIG. 6 illustrates an encryption binding configuration 600 that utilizes the hash 110 of the video player identifier as the encryption key to encrypt the video content or as an encryption key to encrypt the encryption key that encrypts the video content. In particular, the hash 110 is the encryption key itself or is provided with the encryption key to the encryption engine 114. Further, the encryption engine 114 may utilize encryption methodologies other than the hashed block cipher methodology as described with respect to FIGS. 2 and 3. For instance, a stream cipher may be utilized that encrypts the video content with an encryption key without an initialization vector. Further, a block cipher may be utilized with an encryption key and an initialization vector, but with the hash 110 being utilized as the encryption key instead of being utilized as the initialization vector or as an operand to an operand to an operation performed prior to encryption as described with respect to FIGS. 2 and 3. For example, the video content provider 106 may generate the hash 110 from the video player identifier to generate the content encryption key (“CEK”). The video content may then be encrypted by the encryption engine 114 with the CEK.

FIG. 7 illustrates a process 700 that utilizes the hash 110 of the video player identifier as the encryption key to encrypt the video content. At a process block 702, the process 700 receives, at a server, a video content identifier and a video player identifier from a video player through a network. The video content identifier identifies video content. The video player identifier identifies a video player. Further, at a process block 704, the process provides the video player identifier to a hash generator to generate a hash of the video player identifier such that the hash is an encryption key. In addition, at a process block 706, the process 700 encrypts plaintext of the video content with the encryption key to generate ciphertext. In one embodiment, the process 800 is utilized when each user has a unique video player. Further, various encryption methodologies, e.g., stream cipher, block cipher, or the like, may be utilized.

FIG. 8 illustrates a process 800 that that utilizes the hash 110 of the video player identifier as an encryption key to encrypt the encryption key that encrypts the video content. At a process block 802, the process 800 receives, at a server, a video content identifier and a video player identifier from a video player through a network. The video content identifier identifies video content. The video player identifier identifies a video player. Further, at a process block 804, the process 800 provides the video player identifier to a hash generator to generate a hash of the video player. In addition, at a process block 806, the process 800 encrypts plaintext of the video content with the encryption key to generate ciphertext. At a process block 808, the process 800 also encrypts the encryption key with the hash to generate an encrypted encryption key. In one embodiment, the process 800 provides the ability to pre-encrypt content, i.e., the content is stored encrypted on a server and is not encrypted at streaming time. In such a configuration, an encryption methodology such as a block cipher may be utilized to allow for such pre-encryption. In contrast, a stream cipher would not be compatible with such a configuration as a stream cipher encrypts in real-time.

The processes described herein may be implemented in a general, multi-purpose or single purpose processor. Such a processor will execute instructions, either at the assembly, compiled or machine-level, to perform the processes. Those instructions may be written by one of ordinary skill in the art following the description of the figures corresponding to the processes and stored or transmitted on a computer readable medium. The instructions may also be created utilizing source code or any other known computer-aided design tool. A computer readable medium may be any medium capable of carrying those instructions and include a CD-ROM, DVD, magnetic or other optical disc, tape, silicon memory (e.g., removable, non-removable, volatile or non-volatile), packetized or non-packetized data through wireline or wireless transmissions locally or remotely through a network. A computer is herein intended to include any device that has a general, multi-purpose or single purpose processor as described above. Further, the system configuration 500 may be utilized to implement the process 700 illustrated in FIG. 7 and/or the process 800 illustrated in FIG. 8.

Although an example of a video player has been illustrated, various other types of media players may be utilized. Further, various other types of media identifiers other than video identifiers may be utilized.

It should be understood that the computer program products, processes, apparatuses, and systems described herein can take the form of entirely hardware embodiments, entirely software embodiments, or embodiments containing both hardware and software elements. If software is utilized to implement the method or system, the software may include but is not limited to firmware, resident software, microcode, etc.

It is understood that the computer program products, processes, apparatuses, and systems described herein may also be applied in other types of computer program products, processes, apparatuses, and systems. Those skilled in the art will appreciate that the various adaptations and modifications of the embodiments of the computer program products, processes, apparatuses, and systems described herein may be configured without departing from the scope and spirit of the present computer program products, processes, apparatuses, and systems. Therefore, it is to be understood that, within the scope of the appended claims, the present computer program products, processes, apparatuses, and systems may be practiced other than as specifically described herein. 

I claim:
 1. One or more computer-readable memory devices comprising stored instructions executable by one or more processors of a server of a video content provider to: receive a media content identifier and a media player identifier in a request from a media player residing on a client device, the media content identifier identifying media content, the media player identifier uniquely identifying the media player, the request being received before the media content is sent to the media player; provide the media player identifier and a binary of the media player to a function generator to generate a hash of the media player identifier and the binary of the media player; perform a first operation on an initialization vector and the generated hash to generate a first result; perform a second operation on a first subset of plaintext and the first result to generate a second result, the plaintext being the media content; encrypt the second result with an encryption key to generate a first set of ciphertext that is bound to the unique media player identifier of the media player residing on the client device; and deliver the first set of the ciphertext and the initialization vector, without the generated hash, to the media player, effective to enable the media player to generate the hash of the media player identifier and the binary of the media player to decrypt the first set of the ciphertext.
 2. The computer-readable memory devices of claim 1, wherein the instructions are further executable to perform a third operation on the first set of ciphertext and the hash of the media player identifier and the binary of the media player to generate a third result, perform a fourth operation on a second subset of the plaintext and the third result to generate a fourth result, and encrypt the fourth result with the encryption key to generate a second set of ciphertext.
 3. The computer-readable memory devices of claim 2, wherein the instructions are further executable to send the second set of ciphertext, without the hash of the media player identifier and the binary of the media player, to the media player.
 4. The computer-readable memory devices of claim 1, wherein the encryption is a block cipher encryption.
 5. The computer-readable memory devices of claim 1, wherein the encryption key is a symmetrical key.
 6. The computer-readable memory devices of claim 1, wherein the encryption key is an asymmetrical key.
 7. The computer-readable memory devices of claim 1, wherein the first operation is an XOR operation.
 8. The computer-readable memory devices of claim 1, wherein the second operation is an XOR operation.
 9. A method comprising: sending, from a video player, a request comprising a video content identifier and a video player identifier through a network to a server, the video content identifier identifying video content, the video player identifier uniquely identifying the video player, the request being sent from the video player before receiving the video content, and being effective to cause the server to generate a hash of the video player identifier and a binary of the video player that is usable to encrypt a first subset of video content using an encryption key and a result of performing a first operation on the generated hash and an initialization vector; receiving, from the server, the first subset of encrypted video content that is bound to the unique video player identifier, and the initialization vector, without receiving the generated hash; generating the hash of the video player identifier and the binary of the video player; decrypting the first subset of the encrypted video content with a decryption key to generate a first result; performing the first operation on the initialization vector and the generated hash to generate a second result; and performing a second operation on the first result and the second result to generate a first subset of plaintext of video content from the first subset of encrypted video content that is bound to the unique video player identifier of the video player.
 10. The method of claim 9, further comprising receiving, from the server, a second subset of encrypted video content, without receiving the generated hash, decrypting the second subset of the encrypted video content with the decryption key to generate a third result, performing a third operation on the first subset of the encrypted video content and the generated hash to generate a fourth result, and performing a fourth operation on the fourth result to generate a second subset of plaintext of the video content.
 11. The method claim 9, wherein the decryption is a block cipher decryption.
 12. The method of claim 9, wherein the decryption key is a symmetrical key.
 13. The method of claim 9, wherein the encryption key is an asymmetrical key.
 14. The method of claim 9, wherein the first operation is an XOR operation.
 15. The method of claim 9, wherein the second operation is an XOR operation.
 16. A system comprising: a server configured as a video content provider; a communication module of the server configured to receive a request from a video player residing on a client device, the request comprising a video content identifier and a video player identifier, the video content identifier identifying video content, and the video player identifier uniquely identifying the video player; a hash generator configured to generate a hash of the video player identifier and a binary of the video player that is utilized as an initialization vector; a processor configured to perform a first operation on a first subset of plaintext and the initialization vector to generate a first result, and further configured to encrypt the first result with an encryption key to generate a first set of ciphertext that is bound to the video player identifier of the video player residing on the client device, the plaintext being the video content; and the communication module is configured to communicate the first set of ciphertext, without the initialization vector, to the video player.
 17. The system of claim 16, wherein the processor is configured to: perform a second operation on the first set of ciphertext and the generated hash to generate a second result; perform a third operation on a second subset of the plaintext and the second result; and encrypt the second result with the encryption key to generate a second set of ciphertext; and the communication module is configured to: communicate the second set of ciphertext, without the initialization vector, to the video player.
 18. The system of claim 16, wherein the encryption is a block cipher encryption.
 19. The system of claim 16, further comprising a database configured to store the video content.
 20. The system of claim 16, wherein the encryption key is a symmetrical key. 